DE1275619B - Circuit arrangement for automatic route search in an end-marked switching network in telecommunications, in particular telephone switching systems - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

H04q

German class: 21a3-38

Number: 1275 619

File number: P 12 75 619.3-31 (A 39054)

Filing date: December 19, 1961

Open date: * August 22, 1968

The invention relates to a circuit arrangement for automatic route search in a multi-stage, end-marked switching matrix with bistable switching elements, in which the switching elements are consecutive Steps are connected by intermediate lines to the intermediate line markers are connected, in telecommunications, in particular telephone switching systems.

There are already such circuit arrangements for automatic path search in multi-stage, end-ίο marked switching fields, in which gas discharge tubes are usually used as bistable coupling elements be used. When searching for a route, the coupling elements are located in the various stages in series, and only the coupling elements are switched from the non-conductive to the conductive state switched, which allow a path between the two end markings. Such circuit arrangements with an end mark, however, have a large number of participants and so on a correspondingly large number of coupling stages have considerable disadvantages. These consist in that at a route search after the end marking has been carried out, the number of switching crosspoints from Step to step from the marking becomes larger and larger, until the other end marking at the other end is found. After that, all other crossing points are again in the non-conductive state switched back because only one crossing point is required for a connection in each stage. This fan-like distribution of the current paths before finding the other end marking point has the disadvantage that the crossing points of the switching stages with a few switched through switching elements have to absorb the high current of the many other coupling elements, which leads to overloads or, with appropriate dimensioning, to insufficient utilization of the remaining coupling elements leads. In addition, the marking current applied by the final marking current source must be relatively high.

In addition, circuit arrangements have been developed in order to avoid fanning out and nevertheless to take advantage of the reduction in the set-up time of a connection in the case of end-marked switching networks. For this purpose, the link groups are marked in fan-like patterns, starting from the end connections, using active link markers. These active link markers are then switched on and off according to a specific program. This arrangement has the disadvantage that it behaves a circuit arrangement for automatic route search in an end-marked switching matrix in
Telecommunication, in particular
Telephone exchanges

Applicant:

Automatic Electric Laboratories, Inc.,

Northlake, JH. (V. St. A.)

Representative:

Dipl.-Ing. H. Görtz, patent attorney,

6000 Frankfurt, Schneckenhofstr. 27

Named as inventor:
Max S. Macrander,
Wheaton, JIl. (V. St. A.)

Claimed priority:

V. St. v. America March 20, 1961 (96 957)

This requires a lot of effort, especially in that provision is made for it it must be ensured that busy links are not marked.

In addition, there is already a circuit arrangement for a multi-stage switching network with bistable switching elements known, which also has an intermediate marking between the individual coupling stages by active link markers. To keep the fan flow low, the coupling elements switched through in the course of such a route search are not replaced by a DC, but held by an alternating current that is generated by an alternating current source and is switched to the intermediate lines to be held. This turns them into gas discharge tubes formed bistable coupling elements held in the conductive state. Through this alternating current supply the result is a lower holding current, which means that fanning out is less of a problem. The whole Circuit arrangement, however, results in a very considerable effort, so that the number of stages of the switching matrix cannot be increased arbitrarily despite the low holding current.

The invention is based on the object of fanning out in the switching network without special circuit measures to avoid. Everyone should

809 597/79

Advantages of end-marked multi-stage coupling F i g. 1 is a schematic diagram of a part

fields are obtained without simultaneously being a cross-point switching matrix according to the invention disadvantages appear. manure,

In a circuit arrangement for automatic 'Figs. 2 and 3 graphic representations of the Path search in a multi-stage, end-marked 5 the marked connection or at one of the first Switching network with bistable switching elements, in the case of intermediate level nodes during progressive which voltages occurring in the coupling elements of successive path searches, Stages connected to one another by intermediate lines

According to the invention, each link is a typical arrangement for a progressive path Passive link marker individually search process,

ordered, which consists of a capacitor and a F i g. 5 is a schematic block diagram of a

consists of this parallel resistor and part of a crossover point switching network in which the assigned intermediate line with a constant - a combination of progressive path search voltage potential connects, which is used in the intermediate process and progressive marking interconnections at the outputs of the first stage 15,

from the input marking potential by at least F i g. 6, 7 and 8 are schematic block diagrams

the breakdown voltage of the bistable coupling of arrangements in which for the progressive elements in the direction of the initial marking potential procedure provided in the central part of the arrangement differentiates, and the input marking connection elements will be used, potential applied via a series resistor. 20 The invention can be used in numerous known

This ensures that the route search is preceded by multi-level cross-point switching networks many stages of the switching matrix takes place in such a way that we can see. With such a switching network in each coupling stage only one coupling element each switching stage a plurality of switching matrices switched through for each connection to be searched for. Each matrix has a number of input lines is. In this way, all possible combinations, as well as a number of output lines, and every single nation are created through the entire switching network throughput line is individual with each output line checked sequentially until a path connected between segregated crosspoint switches. as the two end marker points is found. Crossover switch is suitable for any purpose in each stage only one coupling element for each speaking bistable arrangement, for example gas connection path is switched through, the current 30 is filled tubes or various semiconductor devices all coupling elements are the same, so that transitions. To be applicable for the switching arrangement too The device should be in a stable state if individual elements are subjected to loads or insufficient loads use of the other elements is avoided. with very high impedance, according to the blocking addition the marker power source only needs state, and a stable state with very low simple current to hold the bistable impedance, corresponding to the transmission-to-coupling elements to deliver. This passive intermediate stand, own. One common in such arrangements line markers mean a very low level of used device is a four-layer semiconductor wall, because they work completely independently. arrangement with two connections according to the The characteristics of the bistable Kop- USA.-Patent 2,855,524 used. An electronic telescope element are also not critical, only a 4 ° signaling switching system with switching arrangements with gas safety is required be that the DC-filled tubes go from the USA.-patent potential of the passive link markers 2 955 165, and in column 41 of this patent each Another level of the potential of the twin is given further prior art, the between lines of the previous stage by min- suitable switching arrangements disclosed, at least the maximum tolerance of the breakthrough 45 F i g. 1 is a schematic diagram of a voltage of the coupling elements in the direction of the off part of a crossover point switching network from which aisle marking potential differs. the basic idea of the invention emerges. the In order to find the crossing point elements 11 to 16 and 21 to 28 Coupling elements in the inventive circuit should be Shockley four-layer diodes, their nominal arrangement to be marked as already tested, 50 breakdown voltage is selected so that it is at the discharge time constants of the i? C elements must be 40 volts from the high-resistance to the low-resistance The passive link marker is designed to flip state. It was found that this be that when looking for a free switch-through value depends on the speed with which the way through the coupling matrix to a marked breakdown voltage is applied. For an opti output each link once activated 55 times function in an arrangement in which the minimum as long as drive through the capacitor voltage is used according to the invention, this should is marked as occupied until all possible speed dependencies are as small as possible are checked. However, it is also hold up. A minor change to the Thoughtful and the principle is not detrimental, if the breaking stress with the used speed Time constants are shorter, so that under 60 should however be present so that if the span circumstances a very limited number of paths at a plurality of intersection points is checked simultaneously. is created at the same time, only one crossing point in Further advantageous refinements of the invention pass over the low-resistance state and thereby subject matter of the subclaims are to be prevented from addressing others. Take the intersection. In the following, 65 point elements are simply referred to as "intersection points".

Embodiments with reference to the drawing F i g. 1 illustrates three stages of an arrangement explained in more detail. It shows only the crossing points in each step,

5 6

which can be present in possible paths, starting from an adjoining point, all of the intersection points in the end T1 . In order to further simplify the explanation of the blocking state, whereby all interconnection conformations are further simplified, each input line capacitors is discharged via the parallel resistors, a stage shown in such a way that it gives access to only the interconnections 81 to 84 are now marked,

has two output lines. 5 and there can be a path to one of the intermediate lines

Each intermediate line has a passive marker 91 to 98 can be made by attaching to this one with a capacitor with parallel negative voltage is applied before lying resistance, which between a front of the capacitors in the Zwischenleitungsmarspannungsquelle and the intermediate line. Each kierern to have largely unloaded.

The end line is connected to ground via a resistor. 1 in the following is a continued

bound. The input line from the terminal Tl is border routing method described. This

via a diode 42 to a maximum of +25 volts. This procedure allows the order to

Line can optionally be marked by marking the end of the key, for example Tl and Tl

Switch 51 is closed and thereby the line is found and a free path is found and between the

is made via the resistor 41 with a voltage source 15 sen terminals. First of all, the

+ Vb is connected. Switch Sl closed, whereby the intermediate

A progressive marking according to the invention line 97 via the resistor R 7 -3OVoIt andung is first described with reference to FIG. 1 explained. and the marking of the connection. Assume that all intermediate lines T 2 are made. Then the switch 51 is closed, 91 to 98 to the right of the intersection points 21 to 28 over 20 to mark the terminal Tl over which their respective resistors 31 to 38 are connected only with resistor 41 the potential + Vb to the line 61 ground and that the free intermediate application. The possible crossing point paths going from the line 61 in a fan-shaped manner to the left of these crossing points 21 are then to be marked progressively in the manner described above up to 28, which are accessible from the connection T1. The marking is checked by 25. If initiated during this progressive test closing the switch Sl. If the fungus at the crossing points 12 and 16 in the line voltage of a line 61 rises, either the state speaks and the capacitor C 6, the crossing point 11 or the crossing point 12 is sufficiently charged, the next one responds, depending on which one of both the lower crossing point 27, since it has breakdown voltage at its cathode. Assuming there is a 3 ° marking potential of -30 volts. The Widerder intersection point 11 responds, the stands 41 and R 7 are dimensioned so that the zwi-capacitorCl in the way of + Vb over the crosses see the connections Tl and Tl made branch point 11 and the diode 44 to - 20 volts - binding assumes such a voltage level that the source can be charged. If the capacitor C1 has been charged under a sufficiently high potential in the step-by-step path search process, it has broken. The voltages at the free intermediate lines point 14, which were not marked during the crossing point 13 or the crossing test method, but not the crossing point 12, correspond to the discharge of the capacitors. This is due to the more negative ren in their marking circles after some time. Bias level of -25 volts on the cross F i g. 2 is a graphic representation of the cutting points 13 and 14. If the intersection at connection Π responds during the advancing point 13, the capacitor C 3 is charged, route search method when the connection is marked until the intersection point 14 responds. Simultaneously with ses Tl. First the switch 51 is closed, the response of the intersection point 14 falls and at time ti the potential at the intersection point 13 reaches the breakdown value of approximate blocking voltage, approximately +20 volts, due to the intersection point 11 applied to it its cable 45 way 40 volts, so that the crossing point responds, method on the intermediate line 81 and - 20 volts on the - 20 volt mark on the intermediate line of its anode, from the intermediate line 82 over the 71 is then over the crossing point 11 to the intersection point 14. The Kon line 61 is now charged. The capacitor C1 charges up to the capacitor C 4 until the crossing point 12 comes on, until the time ί 2 the voltage speaks approximately. The intersection points 11 and 14 drop here- 50 15 volts and the intersection point 13 falls off as a result of the reverse voltage applied to them. speaks. Then a potential of −25 volts is given across the intersection points 15 and 16, the intersection points 13 and 11 now speak to the line 61 one after the other in a manner similar to that which took place previously. The capacitor C 3 then charges, responding to the intersection points 13 and 14, until the voltage at time t3 again increases approximately in a sequence that rises from the respective 15 volts, the intersection point 14 depends on the breakdown voltages. If now-speaks and the -25 volt potential of the Zwimehr, the jRC time constant of the capacitor discharge line 82 via the crossing points 14 and 11 is large, so that the line 61 occurs at the capacitor C1. Now the intersection drops its sufficiently positive voltage, around point 13. The capacitor CA charges until the renewed response of the crossing point 11 to prevent the approximation of potential on the line 61 at time i4, the capacitor in the meantime reaches 20 volts and the crossing point 12 responds to the line behind the last mentioned cross as well as the crossing points 11 and 14 draw off the level of + 25 volts and fall the fall. Thereupon the 20 volt potential from the crossing points 12 and 15 or 16 is applied when the intermediate line 72 is applied to the line 61. The current through the parallel resistor, less than the capacitor C 2, charges until the time tS is the Kreu holding current. This is ensured by responding for the junction point 16 and the -25 volt potential, the parallel resistance of the intermediate line marker, goes from the intermediate line 84 to the line 61, provided that a sufficiently high value is used. Now- Then the capacitor C 6 charges until the Po-

potential at time t6 again approximately + 10 volts and the intersection point 27 responds. The voltage then rises until it reaches a stable, slightly positive value at time ti. F i g. 3 is an illustration of the voltage appearing on the intermediate line 71.

It should be noted that the maximum voltage that can be applied to a crossing point is around to make him speak, equal to the sum

Part of a path between line 401 on the right and line 451 on the left of the assembly can be used. The arrangement comprises the Stufest with the matrices 5 4 ^ 41, 4 ^ 42 and 4 A3, the stage B with the matrices 4Bl, 452 and 4B3 and the stage C with the matrices 4Cl 4C2 and 4C3. Each of the intermediate lines 411 ^ 4 to 433.4 leading from the stage to stage B is provided with a passive intermediate line marten nominal breakdown voltage, denoted by Vs , which has a capacitor that can be connected and a resistor , which can be denoted by Vd and the one with a bias level. The voltage source shown in Fig. 1 of -20 volts is connected. Each bias potentials were selected on the basis of one of the intermediate lines 411 B to 433 B _1, which range between a value Vs equal to 40 volts and a value Vd equal to level B and level C , has a value similar to -5 volts. The Vd voltage stage is used to provide a -25 volt bias source to ensure that all connected passive link markers are used during the test. Crossing points of a stage are checked. The lines to the right of the stage are optionally arranged in such a way that it is marked on the Mar- by connecting the bias potential 403 applied to each stage by closing the switch Merer to a potential + Vb 25 volts, otherwise they are level by the value Vd different. This notes firmly at +25 volts. The lines to the left of stage C ensure that progressing from stage to stage and, by closing switch 453, and in this case unsuccessfully, backwards every free intersection through connections made with a preload point intermediate line is checked. Occupied force source of - 30 volts optionally marked. If there are intermediate lines, there is a connection between the potential at line 401 at approximately ground. Crossing points, at the output coupled connection on the one hand and the potential OVoIt on the terminals, do not respond to line 451 coupled connection on the other hand, then only half of the breakdown is to be established at them, line 451 is first connected by voltage. So is of the details in FIG. 1 Closing the transistor switch 453 marMert. The bias potentials given in this way, the potential 403, which is permanently applied to the line 61 by closing the transistor switch diode 42, is then marked on the line 401 and the progressive equal to ¹ Iz Vs + Vd. The bias potential applied to each of the intermediate line ends from line 401 to 71 and 72 is initiated to seek a path to line 451 , equal to - V2 Vs. The bias potential at the line 401. After a path is found and established, intermediate lines become 81 to 84 is the same - ¹ IzVs- Vd. 35 the switch 453 is open, while the switch 403 in the intermediate line following the next stage remains closed in order to maintain the connection.

gen, the potential applied to mark an intermediate line, for example to mark the intermediate line 97, by closing the switch S2 is equal to −V ₂ Vs − Vd.

The important feature of the ongoing method of the invention is that never more than one branch of the arrangement needs to be supplied with holding current. Furthermore, the circuit is preserved. Holding current then flows from + Vb via switch 403, further from line 401 through a crossing point of each stage to line 451 and so -40 then via diode 454 and a winding of transformer 452 to ground. After tripping, the switch 403 is opened to block the holding current and throw off the connection.
F i g. 5 is a schematic block diagram of a

layout for the inner link marking 45 part of a crossover point switching network in which simple. The capacitor and the shunt resistor are used in a method that a combination of each link marker can be chosen so as to represent the progressive path finding method and the one that represents the impedance for tone or self-progressive marker and that for the higher frequencies is negligible. This is especially the case when the intersection point of an extended arrangement reduces the time required for a negligible speed-dependent manner. If, as in connection with gigkeit exhibit. If this is the case, the F i g. 1 explains that the progressive process is initiated on charging the crossing points of each link only one connection and at the marker required time is limited to values below other side of the array no connection to one microsecond. With aus- 55 Mert is, the intersection points sought ShocMey four-layer diodes speak one after the other, were times and drop out. In the arrangement according to FIG. 1 of 4 microseconds per capacitor is achieved, which occurs when switch 51 is closed, but the check of 200 crossover points per milli of switch S 2 remains open. Allowed after the last second. Has addressed the intersection and has fallen off,

Fig. 4 is a schematic block diagram of a 60 are all of the port originally marked typical arrangement for a progressive path - fan-shaped outgoing free intermediate lines search procedure. The drawing gives a simplified three-stage with a marking voltage of opposite polarity Arrangement again. Each stage is marked with three tat groups, with the starting time of the same Crossing point matrices shown, where each measure is represented by the i? C discharge time constant of the intermediate trix a total of nine intersection points in an instruction marker in these intermediate lines of 3 x 3 between three input lines is correct. The crossing point arrangement can be so and has three output lines. In each matrix must be taken that the markings are on the agent only those crossing points shown as the stage of the arrangement progresses to. The i? C-Ent-

9 10

Charge time constants of the level B link markers are also accessible with

should be chosen so that the marking voltage marks - 25 volts.

at a relatively low speed, after the progressive marking process, based on the loading time, subsides. The marking voltage, starting from the line 501, is completed, can then be viewed as being stored for a certain period of time, the line 551 is viewed by closing the transistor. Then switch 553 can then be marked. The crossing points of the other side of the arrangement from a progressive matrix SEI are checked in order to be initiated by the intermediate points of the route search process. The lines 511 D to 531 D have a free first branch to be selected, which has a crossing point in the middle part and from there, as in connection with FIG. 1 reached, on the other side of which there is a marking voltage corresponding to the purpose described, progressively a free intermediate line, can be found as a result of the intermediate lines 511 C to 593 C in front. The next progressive marking cycle this time when a free intermediate line 511 C respond to the crossover point, and a connection 593 C is established by addressing a crossover point. Since only stage D is encountered at any given time, this intermediate branch will arrive, multiple lines 15 line will be marked with a positive voltage. Which prevents. F i g. 5 shows a five-stage arrangement, previously marked intermediate line 511 B to 539 B in which this combined method is used, marked with approximately -25 volts. Hence will. Illustrates only those matrices speaks the intersection point in the step C of, the arrangement at a connection between whereupon consecutively the crossing points in an input coupled to the line 501 left arrival 20 stages B and A in the on line 501 lead circuit and a coupled to the line 551 the path to respond. A hair-proof connection can participate. So in test current flows from the source + Vb over the stage a matrix5 Al, in stage B three matrices switch 553 and the five crossing points to the line 551 to 5B 3, in the middle stage C nine matrices tung501 and then over the switch 503 after 5Cl to 5C9, in stage D three matrices 5Dl to 25 - Vb. The resistors in series with the two transistor circuits 5D3 and a matrix 52il in stage E should be chosen in such a way that it is clear. The lines to the left of stage A are so that the potential on line 501 is slightly power when they are marked, firmly at - 30 volts and positive. The current then flows through the diode 504 via switches, for example the transistor and a winding of the transformer 502 to ground. switch 503, by connecting to a bias 30 The switch 503 can then be opened and voltage source - Vb optionally marked. The connection is maintained. In order to trigger an intermediate transition from stage A to stage B , switch 553 is opened to block the holding lines 511 ^ 4 to 513 A with passive intermediate currents and thereby provide the connection with discharge line markers, which throw a condenser. It should be noted that in the manufacture sator have a resistor in parallel 35 of the connection as it progresses from the middle and with a bias source of +15 volts level C on the marked line 501 is connected as a result of the. The intermediate lines 511S extending between stage B and the structure of the arrangement only a single route stage C until is determined.

539 B have passive Zwischenleitungsmarkierer that the progressive process, in a

can be used with a bias source of + 20 volts

are bound. The intermediate lines in the middle part of the arrangement extend from stage C to stage D

the intermediate lines 511 C to 593 C are split and are each used as a »switching element«

Active intermediate line markers with a condenser or "partial organ" designated units are used

sator on, which are a with a bias source from. Switching arrangements of this type are in the above

- 15 volt connected capacitor is in parallel. 45 mentioned US Pat. No. 2,955,165 reproduced between stage D and stage E. For a transmission switching arrangement, one of the intermediate lines 511 D to 531 D has a suitable arrangement, also from the USA patent specification, sive intermediate line markers with a condenser 2,883,470. The last-mentioned patent shows a sator, which is equipped with a bias voltage source from a tap changer, there with an "unlocking scanner"

- 10 volts connected resistor is in parallel. The lines are to the right of stage E when they are checking. The two connections of a connecting element are marked, firmly attached to a bias voltage source of + 32 volts that can be used in the desired connection and can optionally be marked, in, by means of a fanning out arrangement to which they are switched via switches, for example the transistor Crossing points of the marked connection switches 553, marked with a voltage source + Vb connections. When the tracer can be tied to a. switching device marked on both sides

If a connection is to be established between the one on the line, this is selected and the connection is established.

501 coupled connection and placed on the line.

551 coupled connection found and connected with the one used in this type of arrangement

are made, the line 501 is initially through 60 progressive procedures, there are three possible-

Closing the transistor switch 503 is marked. The abilities: (a) the application of a progressive

Progressive marking then runs to the central marking, marked fan-shaped pattern

level C. All of the line 501 via the matrix intermediate lines, starting from the two

SAl to stage B reaching free intermediate line connections and ending at the switching element, to be

gene will generate with a potential of -25 volts mar- ⁶ 5 and then the switching organs through

kiert. Check all free intermediate lines between the one step switch and a through-connection

Level B and Level C to choose from the marked organ that allows a connection; (b)

Mark the intermediate lines between the stage and the end connections, then the through

to check switching elements by means of a step switch, so that each switching organ a step-wise progressive Wegesuchverf ahren in the direction of the Connections initiates, and a successful search for the marked connection on both sides To choose switching device; (c) Use the progressive marking process to create a fan-shaped Pattern of marked intermediate lines, starting from the connections and at any stage in

corresponding line on the other, not shown, side of the arrangement are made the switch 753 and the corresponding switch, not shown, on the other side of FIG 5 Arrangement closed to mark both connections. The scanner 790 then unlocks in turn the switching organs. When the switching element 7/1 is unlocked, the transistor switch becomes 703 closed. A progressive path

of the arrangement as ending in FIG. 5, the switching elements then take place on both sides of the arrangement by means of a tap changer. It is assumed that between the suffering end lines towards the connection port of the line 761 and the connection progressing the path search process into the device interconnect 711 with a different line in on each side to find a marked connection on the other side of the device th connecting line to be initiated and the 15 is spoken. Then there is this way to choose a through-switching element , which finally has the essential success on both sides of the intermediate line 713 A. Examples of these three embodiments are based on ground potential. The progressive testing is illustrated in Figs. In each process from the switching element 7/1 from these figures, only one half of the arrangement is not shown to address the crossing point, since the arrangement on both sides of the intermediate line of the switching element is symmetrical. Also in the one half of the arrangement shown, only that part of each stage is shown, which is in a
Connection to the port shown
can be included.

F i g. 6 shows part of a six-stage arrangement. The switching elements 6/1 to 6J9 provided in the middle part and parts of the stages are shown

7/1 and the intermediate line 713 A. If the two marked connections have been found, which is noticeable by the fact that there is ground on both sides of the switching element, the gate switch G sends a signal to the scanning device 790 to detect the relevant To choose switching organ and establish the connection. The transistor switch 703 is switched off for the purpose of triggering.

A, B and C. One of the switching organs, 6/1, is Fig. 8 shows part of a six-stage connection

shown in detail, insofar as this is for the continuous order with the through-step provided in the middle part Route search procedure is important. organs similar to those according to FIG. 6 and 7. This one

To establish a connection, the line arrangement is carried out according to the method according to FIG. 5 marked in each device 601 by closing the switch 603, half applied. The line 801 is marked by while another line on the opposite side of the switch 803 is closed, while the lower, unillustrated side of the arrangement 35 corresponding line is marked on the other, not correspondingly. The free visible side of the arrangement in a similar manner intermediate lines are then progressively marked by. As a result, in the stage there is a marking that progresses towards the end lines in the direction of the switching, in which the free organs are marked. The free intermediate lines be- intermediate lines of the intermediate lines 811 ^ 4, see the steps A and B and the free intermediate 40 and 813 S12A. 4 marked with negative potential lines between stages B and C that are on the. If the scanning device 890 can participate in the through connection, switching element 8/1 is switched with negative, the switch 851 is marked with a potential. The switching devices are switched, and in both halves of the arrangement, a progressive path search process then takes place one after the other by means of the unlocking scanning device, and another is checked. The transistor switch 653 of the switching element prepared in advance of one of the intermediate lines between the stages is closed in order to apply marking potential to B and C, which extend via stage B to a marking to the switching element intermediate line, on every th intermediate line of the intermediate lines between half of the arrangement. levels A and B is examined. Then a through-connection element, which is grounded on both sides, receives a connection to the connection intermediate potential after its transistor switch 50 device 801 is established. If it is found that a connection 653 is switched on, outputs a signal to the scanning device 690 via a gate circuit G to those marked on both sides of the arrangement. As a result, lines are available, the scanning is interrupted by the occurrence and the relevant ground potential is selected on both sides by the gate switching element. The connection is established with circuit G a signal to the scanning device 890. Put the transistor switch 603 on the line 55 so that the switching element is selected and the device 601 and the corresponding switch on the opposite connection are established. The switch 803 is then switched off and the connection is maintained, switched on, at the opposite end of the arrangement. For the purpose of interruption, the switch is turned off. For triggering, the transistor 851 is turned off. 653 switched off in the switching device, whereby the Another possible design of an arrangement

Interrupted holding current and the connection off 60 _w ith gating organs using the discarded is. step-by-step procedure is that a

F i g. 7 shows a part of a six-stage cross-plurality of free through-connection organs with a central point switching network with the marking pulse or step provided in the middle section so that Nen switching organs similar to those in FIG. 6 represent each switching element a progressive mark. Here, however, the advancing path is searched in accordance with the arrangement according to FIG directs from the switching element in the direction of. As a result, all free twists and turns Connections made. Should z. B. an interconnection up to a certain point, example binding between line 751 and a corresponding line beyond the first stage

each side of the switching element, marked by their capacitors are charged. Is now a progressive route search process on a marked Connection initiated from either side of the arrangement can be one on either side of the arrangement Way to be found to a free switching organ. The switching organs must with this special embodiment be divided into two symmetrical halves. The two half-switching organs, the ground potential received from the relevant connections must then be completed connected to each other. This greatly reduces the time required is to find a free path and connect. Other variations lead to even faster solutions to help establish a port-to-port connection reduce the total time required.

Since the breakdown voltage of four-layer diodes or other usable bistable anao Orders depends on the speed with which the voltage is applied, it is understood that the breakdown voltage in the claims relates to the dynamic breakdown values.

Since four-layer diodes have a certain internal capacitance, it is possible that they are from the high-resistance be switched to the low-resistance state without a breakdown voltage being applied, which exceeds the static value. This is the case when the time derivative of the applied voltage is the The holding current of the arrangement divided by its capacitance measured in the off-state exceeds, wherein the current can exceed the holding value and therefore switch the diode to a low-resistance state. The invention can be implemented in an arrangement in which this effect for switching the Diodes is used.

The invention can also be practiced in embodiments in which devices with three or more connections can be used. For example, four-layer diodes can have an additional Have electrode connected to one of the inner layers and a corresponding circuit is connected to improve the switching properties. Gas-filled tubes can also have a control electrode have between cathode and anode. Arrangements with such devices fall also within the scope of the invention.

The invention has been described above in its essential features in connection with specific arrangements described, but it should be understood that this is for illustrative purposes only and is not to be construed as limiting the scope of the invention.

Claims (10)

Claims: 55 1. Circuit arrangement for automatic route search in a multi-stage end-marked switching network with bistable coupling elements, in which the coupling elements of successive stages are connected to one another by intermediate lines, to which intermediate line markers are connected, in telecommunications, in particular telephone switching systems, characterized in that each intermediate line (71, 72 ) a passive intermediate line marker (Cl, Rl; C2, Rl) is individually assigned, which consists of a capacitor (Cl, C2) and a resistor (Al, R2) connected in parallel and connects the assigned intermediate line to a direct voltage potential (-20 volts) , which at the intermediate lines (71, 72) at the outputs of the first stage (11, 12) of the input marking potential (+ Vb) by at least the breakdown voltage (40 volts) of the bistable coupling elements (11, 12) in the direction of the output marking potential ( - 30 volts) and that the input marking pot ential (+ Vb) is applied via a series resistor (41). 2. Circuit arrangement according to claim 1, characterized in that the direct voltage potential (-25 volts ...) of the passive intermediate line markers (R 3, RA ...) of each further stage (13, 14 ...) is different from the potential of the intermediate lines (71, 72) of the previous stage (11, 12) differs by at least the maximum tolerance (5 volts) of the breakdown voltage of the coupling elements (11, 12, 13, 14 ...) in the direction of the output marking potential (-30VoIt). 3. Circuit arrangement according to claim 1 or 2, characterized in that the discharge time constants of the ÄC elements (Rl, Cl; R2, C2 ...) of the passive link marker are designed so that when looking for a free through-connection path through the switching matrix to a marked Output (T 2) each intermediate line (71, 72, 73 ...) that has been activated is marked as occupied by the capacitor voltage at least until all possible switching paths have been checked. 4. Circuit arrangement according to one or more of claims 1 to 3, characterized in that such voltage potentials are applied to the end points (Tl, T2) of an occupied switching path that the coupling points of all occupied intermediate lines are prevented from responding when a new search for a switching path is carried out. 5. Circuit arrangement according to one or more of claims 1 to 4, characterized in that in each case an output line (T 2) on the other side of the switching matrix before or at the same time with the input line (UTl) can be marked and that after the complete construction of one Through switching path from the marked input line (Tl) to the marked output line (T2) the search is aborted. 6. Circuit arrangement according to one or more of claims 1 to 5, characterized in that the bistable coupling element of a middle stage (z. B. 5Cl) of the coupling network by the DC potentials of its mutually adjacent passive link marker (511 b, SlIc) normally in the reverse direction is biased that an end marking potential (- Vb) first switched to an end point (501) of the switching network marks all free lines up to this stage (5Cl) and the voltages of the capacitors of the passive link markers maintain these markings for the duration of the test, and that a connected to an end point (551) at the other end of the switching matrix tes end marking potential (+ Vb) checks the intermediate lines from the other end up to the stage (5 Fl) until the bistable coupling element switches through due to the capacitor voltages on both sides and establishes a connection path between the marked end points (501, 551) . 7. Circuit arrangement according to one or more of claims 1 to 6, characterized in that that switching elements (6/1 to 6/9) are provided in the middle of the switching network, between which and the end points respectively connection paths are searched for automatically. 8. Circuit arrangement according to claim 7, characterized by a scanning device (690) which successively scans the switching elements (6/1 to 6/9). IO 9. Circuit arrangement according to claim 7 or 8, characterized in that the switching elements (7/1 ...) as starting points for a route search in both directions to the marked endpoints can be marked for the delivery of a marking potential. 10. Circuit arrangement according to claim 7 or 8, characterized in that the two End points as starting points for a route search to the switching organs for delivery of a marking signal can be marked. Considered publications:
German publication no.1000458,
1055 057; British Patent No. 822141;
U.S. Patent Nos. 2,859,284, 2,883,470,
855, 2951124, 2 955165. For this purpose 2 sheets of drawings 809 597/79 8.68 © Bundesdruckerei Berlin